ANN for constraint optimization problem

Question

studentU il 27 Nov 2016

0
Link

Link diretto a questa domanda

https://it.mathworks.com/matlabcentral/answers/314236-ann-for-constraint-optimization-problem

Modificato: studentU il 1 Dic 2016

hello,

How do i modify my ANN algorithm, by incorporating some constraints to perfom my obtained result. the matlab code used is generated from Neural Network Toolbox.

 function [Y,Xf,Af] = ANN_Function(X)
% ===== NEURAL NETWORK CONSTANTS =====
 % Input 1
 x1_step1_xoffset = [-0.964339227389144;-0.906927494859787;-0.9643288955237];
 x1_step1_gain = [1.03826501814344;1.06861700687107;1.27340625419393];
 x1_step1_ymin = -1;
 % Layer 1
 b1 =  [-1.3371193654695128217;-3.7243723447930885406;0.59020209217794505907;-0.26942 281438778381553;-0.084790990077469749475;-0.287833517416886564;-0.6199588700217847359;0.87036361559242081398;1.1136596091577191103;3.5728692098803582766];
 IW1_1 = [0.62172489473929637427 -1.1539538428995010921 0.40749280432490736503;0.33504097052172682192 2.2754223181903578954 -2.0670552187061321803;-0.97421719994837163714 0.16930737512492399777 0.95638889040809083042;3.453458645614659428 2.4120651149524281465 3.9342055592145062093;2.9998512477370034013 2.2723487424133810286 3.3571622229587347874;-1.6838243946405258011 -2.3995748128279066336 0.36244936598086713309;-3.1423700210823852785 1.3845185332230820485 2.4609517018642876884;-0.39703700607817143942 2.4912130193995269956 -0.16941481846512243536;1.406655675671569572 0.92534256006865256428 0.64325984129225455277;1.5085377777493140794 1.4551527878904193525 -1.3090133612083598713];
 % Layer 2
 b2 = [-0.28647967632293369622;-0.77689684809120063136;0.23567045137827014045;-0.50614562961496167848;0.17775471570313430836;0.39409286123122444501;-0.23743319675300361693];
 LW2_1 = [-1.2595809845665446591 0.52253536564831837286 1.6575450213582203496 1.4444644615739332671 -0.79927746466752380705 -0.49440949393277561219 -1.0291039534117272236 -0.10205229528755178914 -1.783179386992490123 0.012007511957539542674;-1.8160587258194498261 0.16525212307258660416 -0.35634974797682900105 0.61911944611294977836 -0.55104180525241264199 0.36270218166368617396 0.70227078264624087645 -0.69192422904692441055 0.63741286998972901401 0.078380036138073788665;-0.39987089599785630156 0.0015263660888982231219 -0.32703999255710186622 -1.0870691355791675115 0.68183572942635206626 0.20086063975571505358 0.53707692508704663048 -0.043958739282595582498 0.30170293659756891591 -0.40387165805595148793;-0.42538078713443683299 -0.41243046298959784579 0.09360967585146644232 -0.54902810742656438237 0.27858672713463300541 0.13466521369669071095 -0.31684402239022979586 -0.016110146899087046668 0.18209067234932024837 -0.38144681930811946691;0.78489623544097297803 0.064197561813166229006 -0.14703146723552590336 0.045763727795912277629 -0.044493781097574965078 0.023102496123388799321 0.19498160438730580135 0.42399577006788119471 0.068627392557574939946 0.2774573470874529546;0.28300904777281810087 -0.040045961378933660202 -0.048322484065649526364 0.23633721304470370339 -0.28761021912207535012 0.22386822762508534757 -0.095795332741767574847 0.31901549272383256106 0.17453188621906071121 -0.40095786179528114523;0.2537157491011907684 -0.037837226082635302959 -0.044856312727524147443 0.24018253583883578117 -0.28974054247799801987 0.23561178051146219881 -0.095989508380685484301 0.30576014862164185848 0.18195538033206490325 0.22157365239611195862];
 % Output 1
 y1_step1_ymin = -1;
 y1_step1_gain = [1.21212121212121;1.53846153846154;0.8;3.33333333333333;1.66666666666667;2;2];
 y1_step1_xoffset = [-0.785398163397448;-0.523598775598299;-0.261799387799149;-0.174532925199433;-0.349065850398866;-0.523598775598299;-0.523598775598299];
 % ===== SIMULATION ========
 % Format Input Arguments
 isCellX = iscell(X);
 if ~isCellX, X = {X}; end;
 % Dimensions
 TS = size(X,2); % timesteps
 if ~isempty(X)
    Q = size(X{1},1); % samples/series
 else
    Q = 0;
 end
 % Allocate Outputs
 Y = cell(1,TS);
 % Time loop
 for ts=1:TS
    % Input 1
    X{1,ts} = X{1,ts}';
    Xp1 =  
 mapminmax_apply(X{1,ts},x1_step1_gain,x1_step1_xoffset,x1_step1_ymin);
    % Layer 1
     a1 = tansig_apply(repmat(b1,1,Q) + IW1_1*Xp1);
    % Layer 2
    a2 = repmat(b2,1,Q) + LW2_1*a1;
    % Output 1
    Y{1,ts} = 
 mapminmax_reverse(a2,y1_step1_gain,y1_step1_xoffset,y1_step1_ymin);
    Y{1,ts} = Y{1,ts}';
end

% Final Delay States Xf = cell(1,0); Af = cell(2,0);

% Format Output Arguments if ~isCellX, Y = cell2mat(Y); end end

% ===== MODULE FUNCTIONS ========

% Map Minimum and Maximum Input Processing Function function y = mapminmax_apply(x,settings_gain,settings_xoffset,settings_ymin) y = bsxfun(@minus,x,settings_xoffset); y = bsxfun(@times,y,settings_gain); y = bsxfun(@plus,y,settings_ymin); end

% Sigmoid Symmetric Transfer Function function a = tansig_apply(n) a = 2 ./ (1 + exp(-2*n)) - 1; end

% Map Minimum and Maximum Output Reverse-Processing Function function x = mapminmax_reverse(y,settings_gain,settings_xoffset,settings_ymin) x = bsxfun(@minus,y,settings_ymin); x = bsxfun(@rdivide,x,settings_gain); x = bsxfun(@plus,x,settings_xoffset); end

2 Commenti
Mostra NessunoNascondi Nessuno

Greg Heath il 29 Nov 2016

Why are you dissatisfied with your current code?

Greg

studentU il 1 Dic 2016

Modificato: studentU il 1 Dic 2016

Thank you for your repply,

The current code is made in general case without take into account my fitness function and constraints to obtain the optimal solution!!!

it's work well, but i want to modify it in order to incorpor the constraints.... how can i do it? is it the recurent neural network the best solution in neural network constraint optimizing? Do you have some idea to this perpose?

Accedi per commentare.

Accedi per rispondere a questa domanda.